Atomic view of cosolute-induced protein denaturation probed by NMR solvent paramagnetic relaxation enhancement
The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein st...
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| Published in | Proceedings of the National Academy of Sciences - PNAS Vol. 118; no. 34; pp. 1 - 9 |
|---|---|
| Main Authors | , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
National Academy of Sciences
24.08.2021
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| Subjects | |
| Online Access | Get full text |
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| Abstract | The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein stability is still the subject of considerable debate. Probing the molecular details of the cosolvent effect is experimentally challenging as the interactions are very weak and transient, rendering them invisible to most conventional biophysical techniques. Here, we probe cosolute–protein interactions by means of NMR solvent paramagnetic relaxation enhancement together with a formalism we recently developed to quantitatively describe, at atomic resolution, the energetics and dynamics of cosolute–protein interactions in terms of a concentration normalized equilibrium average of the interspin distance, 〈r
−6〉norm, and an effective correlation time, τc. The system studied is the metastable drkN SH3 domain, which exists in dynamic equilibrium between native and unfolded states, thereby permitting us to probe the interactions of cosolutes with both states simultaneously under the same conditions. Two paramagnetic cosolute denaturants were investigated, one neutral and the other negatively charged, differing in the presence of a carboxyamide group versus a carboxylate. Our results demonstrate that attractive cosolute–protein backbone interactions occur largely in the unfolded state and some loop regions in the native state, electrostatic interactions reduce the 〈r
−6〉norm values, and temperature predominantly impacts interactions with the unfolded state. Thus, destabilization of the native state in this instance arises predominantly as a consequence of interactions of the cosolutes with the unfolded state. |
|---|---|
| AbstractList | The cosolvent effect alters the equilibrium between native and unfolded states of a protein, with denaturant cosolutes shifting the equilibrium toward the latter and osmolyte cosolutes stabilizing the former. Quantitative characterization of the strength of cosolute–protein interactions at atomic resolution is experimentally challenging as these interactions are highly transient and occur at low occupancy. Here, we make use of paramagnetic cosolutes and NMR solvent paramagnetic relaxation enhancement measurements to quantify the interaction of cosolutes with drkN SH3, a metastable protein domain that exists in dynamic equilibrium between native and unfolded states. The current study shows that destabilization of the native state is largely attributable to preferential cosolute interactions with the unfolded state.
The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein stability is still the subject of considerable debate. Probing the molecular details of the cosolvent effect is experimentally challenging as the interactions are very weak and transient, rendering them invisible to most conventional biophysical techniques. Here, we probe cosolute–protein interactions by means of NMR solvent paramagnetic relaxation enhancement together with a formalism we recently developed to quantitatively describe, at atomic resolution, the energetics and dynamics of cosolute–protein interactions in terms of a concentration normalized equilibrium average of the interspin distance,
〈
r
−
6
〉
norm
, and an effective correlation time, τ
c
. The system studied is the metastable drkN SH3 domain, which exists in dynamic equilibrium between native and unfolded states, thereby permitting us to probe the interactions of cosolutes with both states simultaneously under the same conditions. Two paramagnetic cosolute denaturants were investigated, one neutral and the other negatively charged, differing in the presence of a carboxyamide group versus a carboxylate. Our results demonstrate that attractive cosolute–protein backbone interactions occur largely in the unfolded state and some loop regions in the native state, electrostatic interactions reduce the
〈
r
−
6
〉
norm
values, and temperature predominantly impacts interactions with the unfolded state. Thus, destabilization of the native state in this instance arises predominantly as a consequence of interactions of the cosolutes with the unfolded state. The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein stability is still the subject of considerable debate. Probing the molecular details of the cosolvent effect is experimentally challenging as the interactions are very weak and transient, rendering them invisible to most conventional biophysical techniques. Here, we probe cosolute-protein interactions by means of NMR solvent paramagnetic relaxation enhancement together with a formalism we recently developed to quantitatively describe, at atomic resolution, the energetics and dynamics of cosolute-protein interactions in terms of a concentration normalized equilibrium average of the interspin distance, [Formula: see text], and an effective correlation time, τ The system studied is the metastable drkN SH3 domain, which exists in dynamic equilibrium between native and unfolded states, thereby permitting us to probe the interactions of cosolutes with both states simultaneously under the same conditions. Two paramagnetic cosolute denaturants were investigated, one neutral and the other negatively charged, differing in the presence of a carboxyamide group versus a carboxylate. Our results demonstrate that attractive cosolute-protein backbone interactions occur largely in the unfolded state and some loop regions in the native state, electrostatic interactions reduce the [Formula: see text] values, and temperature predominantly impacts interactions with the unfolded state. Thus, destabilization of the native state in this instance arises predominantly as a consequence of interactions of the cosolutes with the unfolded state. The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein stability is still the subject of considerable debate. Probing the molecular details of the cosolvent effect is experimentally challenging as the interactions are very weak and transient, rendering them invisible to most conventional biophysical techniques. Here, we probe cosolute–protein interactions by means of NMR solvent paramagnetic relaxation enhancement together with a formalism we recently developed to quantitatively describe, at atomic resolution, the energetics and dynamics of cosolute–protein interactions in terms of a concentration normalized equilibrium average of the interspin distance, 〈r −6〉norm, and an effective correlation time, τc. The system studied is the metastable drkN SH3 domain, which exists in dynamic equilibrium between native and unfolded states, thereby permitting us to probe the interactions of cosolutes with both states simultaneously under the same conditions. Two paramagnetic cosolute denaturants were investigated, one neutral and the other negatively charged, differing in the presence of a carboxyamide group versus a carboxylate. Our results demonstrate that attractive cosolute–protein backbone interactions occur largely in the unfolded state and some loop regions in the native state, electrostatic interactions reduce the 〈r −6〉norm values, and temperature predominantly impacts interactions with the unfolded state. Thus, destabilization of the native state in this instance arises predominantly as a consequence of interactions of the cosolutes with the unfolded state. The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein stability is still the subject of considerable debate. Probing the molecular details of the cosolvent effect is experimentally challenging as the interactions are very weak and transient, rendering them invisible to most conventional biophysical techniques. Here, we probe cosolute–protein interactions by means of NMR solvent paramagnetic relaxation enhancement together with a formalism we recently developed to quantitatively describe, at atomic resolution, the energetics and dynamics of cosolute–protein interactions in terms of a concentration normalized equilibrium average of the interspin distance, ⟨r−6⟩norm, and an effective correlation time, τc. The system studied is the metastable drkN SH3 domain, which exists in dynamic equilibrium between native and unfolded states, thereby permitting us to probe the interactions of cosolutes with both states simultaneously under the same conditions. Two paramagnetic cosolute denaturants were investigated, one neutral and the other negatively charged, differing in the presence of a carboxyamide group versus a carboxylate. Our results demonstrate that attractive cosolute–protein backbone interactions occur largely in the unfolded state and some loop regions in the native state, electrostatic interactions reduce the ⟨r−6⟩norm values, and temperature predominantly impacts interactions with the unfolded state. Thus, destabilization of the native state in this instance arises predominantly as a consequence of interactions of the cosolutes with the unfolded state. The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein stability is still the subject of considerable debate. Probing the molecular details of the cosolvent effect is experimentally challenging as the interactions are very weak and transient, rendering them invisible to most conventional biophysical techniques. Here, we probe cosolute-protein interactions by means of NMR solvent paramagnetic relaxation enhancement together with a formalism we recently developed to quantitatively describe, at atomic resolution, the energetics and dynamics of cosolute-protein interactions in terms of a concentration normalized equilibrium average of the interspin distance, [Formula: see text], and an effective correlation time, τc The system studied is the metastable drkN SH3 domain, which exists in dynamic equilibrium between native and unfolded states, thereby permitting us to probe the interactions of cosolutes with both states simultaneously under the same conditions. Two paramagnetic cosolute denaturants were investigated, one neutral and the other negatively charged, differing in the presence of a carboxyamide group versus a carboxylate. Our results demonstrate that attractive cosolute-protein backbone interactions occur largely in the unfolded state and some loop regions in the native state, electrostatic interactions reduce the [Formula: see text] values, and temperature predominantly impacts interactions with the unfolded state. Thus, destabilization of the native state in this instance arises predominantly as a consequence of interactions of the cosolutes with the unfolded state.The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states. Denaturants shift the equilibrium toward the latter, while osmolytes stabilize the former. The molecular mechanism whereby cosolutes perturb protein stability is still the subject of considerable debate. Probing the molecular details of the cosolvent effect is experimentally challenging as the interactions are very weak and transient, rendering them invisible to most conventional biophysical techniques. Here, we probe cosolute-protein interactions by means of NMR solvent paramagnetic relaxation enhancement together with a formalism we recently developed to quantitatively describe, at atomic resolution, the energetics and dynamics of cosolute-protein interactions in terms of a concentration normalized equilibrium average of the interspin distance, [Formula: see text], and an effective correlation time, τc The system studied is the metastable drkN SH3 domain, which exists in dynamic equilibrium between native and unfolded states, thereby permitting us to probe the interactions of cosolutes with both states simultaneously under the same conditions. Two paramagnetic cosolute denaturants were investigated, one neutral and the other negatively charged, differing in the presence of a carboxyamide group versus a carboxylate. Our results demonstrate that attractive cosolute-protein backbone interactions occur largely in the unfolded state and some loop regions in the native state, electrostatic interactions reduce the [Formula: see text] values, and temperature predominantly impacts interactions with the unfolded state. Thus, destabilization of the native state in this instance arises predominantly as a consequence of interactions of the cosolutes with the unfolded state. |
| Author | Yoo, Janghyun Chung, Hoi Sung Schwieters, Charles D. Clore, G. Marius Best, Robert B. Okuno, Yusuke |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/34404723$$D View this record in MEDLINE/PubMed |
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| Copyright | Copyright National Academy of Sciences Aug 24, 2021 2021 |
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| Issue | 34 |
| Keywords | drkN SH3 native and unfolded states protein–cosolute interactions transient states NMR relaxation replica exchange molecular dynamics |
| Language | English |
| License | Published under the PNAS license. |
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| Notes | ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14 content type line 23 Author contributions: Y.O. and G.M.C. designed research; Y.O., J.Y., C.D.S., R.B.B., and H.S.C. performed research; Y.O., C.D.S., R.B.B., H.S.C., and G.M.C. analyzed data; and Y.O. and G.M.C. wrote the paper. Contributed by G. Marius Clore, July 13, 2021 (sent for review June 29, 2021; reviewed by Hashim M. Al-Hashimi and Lewis E. Kay) Reviewers: H.M.A., Duke University Hospital; and L.E.K., University of Toronto. |
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| Snippet | The cosolvent effect arises from the interaction of cosolute molecules with a protein and alters the equilibrium between native and unfolded states.... The cosolvent effect alters the equilibrium between native and unfolded states of a protein, with denaturant cosolutes shifting the equilibrium toward the... |
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| SubjectTerms | Animals Biological Sciences Biopolymer denaturation Destabilization Drosophila melanogaster Drosophila Proteins - chemistry Drosophila Proteins - metabolism Electrostatic properties Equilibrium Models, Molecular NMR Nuclear magnetic resonance Physical Sciences Protein Denaturation Protein Folding Protein interaction Protein Unfolding Proteins Solvents Solvents - chemistry src Homology Domains Thermodynamics |
| Title | Atomic view of cosolute-induced protein denaturation probed by NMR solvent paramagnetic relaxation enhancement |
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